Precursor-product relationship of larger to smaller molecular forms of the BAL 31 nuclease from Alteromonas espejiana: preferential removal of duplex exonuclease relative to endonuclease activity by proteolysis

Two molecularly and kinetically distinct major species of the extracellular nuclease BAL 31 from Alteromonas espejiana, previously characterized as the "fast" (F) and "slow" (S) BAL 31 nucleases, have been evidenced to derive from proteolysis starting from a still larger (approximately 120 kDa) precursor nuclease. The expected protease activity in the culture fluid has been confirmed and is strongly dependent on the cell growth phase. The disappearance of the largest nuclease species with the concomitant sequential appearance of first the F and then the S species has been demonstrated for nuclease obtained from culture supernatants as a function of cell growth phase. Nuclease from periplasmic extracts displayed very little of the F and S nucleases. Treatment of purified F nuclease with Pronase or subtilisin readily converted it to species with only a few percent of the native exonuclease activity against duplex DNA but retaining much of the initial activity against single-stranded DNA. Electrophoresis in nuclease-detecting gels demonstrated a parallel conversion of the larger species to one indistinguishable in molecular weight from the S species. The observed loss of exonuclease activity could correspond to the conversion of the F to the S nuclease. However, treatment of S nuclease with subtilisin resulted in a drastic reduction of exonuclease activity of this enzyme on duplex DNA with retention of most of the activity against single-stranded and nicked circular duplex DNA substrates. Evidence of internal proteolysis of the S nuclease could be seen after electrophoresis in denaturing gels but only after the denaturation buffer was adjusted to 6 M in urea. The preferential removal of the exonuclease activity may enhance the usefulness of the BAL 31 nuclease in such applications as heteroduplex mapping.     

On the recognition and cleavage mechanism of Escherichia coli endodeoxyribonuclease V, a possible DNA repair enzyme

Escherichia coli endodeoxyribonuclease V acts at many sites of damage in duplex DNA, including apurinic/apyrimidinic sites, lesions induced by ultraviolet light which are not pyrimidine dimers, adducts of 7-bromomethylbenz[a]anthracene, and, as demonstrated earlier (Gates, F. T., and Linn, S. (1977a) J. Biol. Chem. 252. 1647-1653), it degrades uracil-containing duplex DNA most efficiently. The cleavage rate increases with increasing substitution of uracil for thymine in T5 DNA, with a replacement of one-eight of thymine generating the apparent maximum cleavage rate. However, the apparent reaction limit with DNA containing 3.8% of thymine replaced by uracil corresponds to cleavage at only 6% of the dUMP residues. Evidently, the enzyme recognizes some peculiarities of abnormal DNA structure, but not simply distortions, since some lesions, including pyrimidine dimers, are not substrates. Endonuclease V generates double strand breaks in a constant ratio to single strand nicks, regardless of the substrate. It degrades DNA processively, completing the digestion of one substrate molecule before proceeding to the next. The enzyme also appears to act cooperatively. Cleavage at methylbenz[a]anthracene adducts is usually or always 5' to the lesion. Endonuclease V seems well suited to act as a DNA repair enzyme, surveying the genome for structural distortions generated by lesions for which specific repair systems might not exist.     

Terminally directed hydrolysis of duplex ribonucleic acid catalyzed by a species of the BAL 31 nuclease from Alteromonas espejiana

The extracellular nuclease activities of Alteromonas espejiana sp. BAL 31 are mediated by at least two distinct protein species that differ in molecular weights and catalytic properties. The two species that have been purified to homogeneity and characterized, the "fast" (F) and "slow" (S) enzymes, both possess an exonuclease activity that shortens both strands of duplex DNA, with the F nuclease displaying a much greater (approximately 19-fold) turnover number for this degradation than the S species. In the present article, it is shown that the F species also mediates the terminally directed hydrolysis of a linear duplex RNA, gradually shortening molecules of this substrate through a mechanism that results in the removal of nucleotides from both the 3' and the 5' ends. This degradation proceeds with very infrequent introduction of scissions away from the termini as demonstrated by gel electrophoretic examination of the products of partial degradation, both in duplex form and after denaturation by reaction with CH3HgOH, and by electron microscopic characterization of duplex partially degraded molecules. The apparent Michaelis constant and turnover number have been determined. At equimolar enzyme concentrations in the limit of high substrate concentration, the F nuclease will degrade duplex RNA at a rate 0.021 +/- 0.010 (S.D.) times that for a duplex DNA of comparable guanine + cytosine content. The S species, by contrast, shows very little activity against the duplex RNA substrate relative to that of the F enzyme.     

Sequence specificity of BAL 31 nuclease for ssDNA revealed by synthetic oligomer substrates containing homopolymeric guanine tracts

Background

The extracellular nuclease from Alteromonas espejiana, BAL 31 catalyzes the degradation of single-stranded and linear duplex DNA to 5′-mononucleotides, cleaves negatively supercoiled DNA to the linear duplex form, and cleaves duplex DNA in response to the presence of apurinic sites.

Principal Findings

In this work we demonstrate that BAL 31 activity is affected by the presence of guanine in single-stranded DNA oligomers. Specifically, nuclease activity is shown to be affected by guanine''s presence in minimal homopolymeric tracts in the middle of short oligomer substrates and also by its presence at the 3′ end of ten and twenty base oligomers. G•C rich regions in dsDNA are known to cause a decrease in the enzyme''s nuclease activity which has been attributed to the increased thermal stability of these regions, thus making it more difficult to unwind the strands required for enzyme access. Our results indicate that an additional phenomenon could be wholly or partly responsible for the loss of activity in these G•C rich regions. Thus the presence of a guanine tract per se impairs the enzyme''s functionality, possibly due to the tract''s bulky nature and preventing efficient progression through the active site.

Conclusions

This study has revealed that the general purpose BAL 31 nuclease commonly used in molecular genetics exhibits a hithertofore non-characterized degree of substrate specificity with respect to single-stranded DNA (ssDNA) oligomers. Specifically, BAL 31 nuclease activity was found to be affected by the presence of guanine in ssDNA oligomers.     

Specificity of the S1 nuclease from Aspergillus oryzae.

Conditions are described for digesting single-stranded DNA by S1 nuclease without introducing breaks in double-stranded DNA. The enzyme is inhibited by low concentrations of various compounds of phosphate. Under certain conditions S1 nuclease cleaves the strand opposite a nick in bacteriophage T5 DNA; under other conditions, the enzyme cleaves a loop in one strand of heteroduplex lambdaDNA while leaving the opposite strand intact. S1 nuclease makes many single strand breaks in ultraviolet-irradiated duplex lambdaDNA. Superhelical DNA of phiX174 (Form I) is converted first to a relaxed circular molecule (Form II), and then to a linear molecule (Form III) by cleavage at one site per molecule. Since the cleavage occurs at many sites in the population of molecules, the partially single-stranded regions in phiX174 superhelical DNA are not determined by specific nucleotide sequences.     

Extracellular nucleases of pseudomonas BAL 31. III. Use of the double-strand deoxyriboexonuclease activity as the basis of a convenient method for the mapping of fragments of DNA produced by cleavage with restriction enzymes.

We have previously characterized an extracellular nuclease from Pseudomonas BAL 31 which, in addition to other activities, displays a double-strand exonuclease activity which progressively shortens both strands of linear duplex DNA molecules from both termini. This degradation is accomplished without the introduction of detectable scissions away from the ends of the duplexes. When this nuclease is used to produce a series of progressively shortened samples from a linear duplex DNA, subsequent digestion of these samples with a site-specific restriction endonuclease and analysis of the resulting fragments by gel electrophoresis permits the rapid establishment of the order of the restriction enzyme fragments through the entire genome. This is accomplished by noting from the electropherograms the order in which the various restriction enzyme fragments become noticeably shortened or disappear. Using this method, the five cleavage sites for the endonuclease Hpa I and the single cleavage sites for the nucleases Hpa II and Pst I have been mapped in PM2 bacteriophage DNA. In a more stringent test of the method, 18 of the 24 fragments produced by cleavage of coliphage lambdab2b5c DNA with the Pst I nuclease have been mapped, and five of the six remaining fragments have been assigned to small regions of the genome.     

Isolation and comparison of two molecular species of the BAL 31 nuclease from Alteromonas espejiana with distinct kinetic properties

The extracellular nuclease from Alteromonas espejiana sp. BAL 31 can be isolated as two distinct proteins, the "fast" (F) and "slow" (S) species, both of which have been purified to homogeneity. The F and S species of the nuclease have molecular weights, respectively, of 109 X 10(3) and 85 X 10(3), and both are single polypeptide chains with an isoelectric pH near 4.2. Both species catalyze the degradation of single-stranded and linear duplex DNAs to 5'-mononucleotides. The degradation of linear duplex DNA occurs through a terminally directed hydrolysis mechanism that results in the removal of nucleotides from both the 3' and 5' ends. Apparent Michaelis constants (Km) have been obtained for the exonuclease activities of both species and for the activity against single-stranded DNA of the S species. The Km for the hydrolysis of single-stranded DNA catalyzed by the F species has not been obtained because the reaction velocity was maximal even at the lowest substrate concentrations accessible in the photometric assay. The ratio of the turnover numbers for the exonuclease activities of the two species indicates that the F species will shorten linear duplex DNA at a rate 27 +/- 5 (S.D.) times faster than an equimolar concentration of the S species in the limit of high substrate concentration, while the corresponding ratio for the activities against single-stranded DNA (1.2 +/- 0.1) shows that the two species are similar with respect to hydrolysis of this substrate. In the limit of high substrate concentrations, the F and S species break phosphodiester bonds in single-stranded DNA at rates 1.3 +/- 0.3 and 33 +/- 2 times those for the exonucleolytic degradation of linear duplex DNA, respectively. It has not been established whether the two species are physically related.     

Circular intermediates with missing nucleotides in the conversion of supercoiled or nicked circular to linear duplex DNA catalyzed by two species of BAL 31 nuclease

The extracellular nucleases from Alteromonas espejiana BAL 31 can catalyze the endonucleolytic and/or exonucleolytic hydrolysis of duplex DNA in response to a variety of alterations, either covalent or noncovalent, in DNA structure. The nuclease can exist as at least two kinetically and molecularly distinct protein species. The two species that have been studied, called the 'fast' (F) and 'slow' (S) nucleases, both readily convert negatively supercoiled DNAs to linear duplex molecules and accomplish this conversion through the formation of a circular duplex intermediate containing usually a single interruption in one strand. It is further shown that most of these intermediates contain gaps arising from the removal in a processive manner of one or more nucleotide residues after the introduction of the initial strand break (nick). Considering only the intermediates with gaps, the average number of missing residues is 6.3 +/- 0.5 and 2.8 +/- 0.3, respectively, for DNA acted upon by the F and S enzymes independently of the extent of conversion of supercoiled DNA. The nicks and gaps are bounded by 3'-hydroxyl and 5'-phosphoryl termini. When singly nicked circular DNA is used as the substrate, conversion to the linear duplex form occurs predominantly through a gapped circular intermediate with the same average numbers, within experimental error, of missing nucleotides for the respective nuclease species as found when supercoiled DNA is the substrate. The conversion to linear duplex DNA is much slower when nicked circular DNA is the substrate compared to that found when supercoiled DNA is the starting material.     

Cleavage of Circular, Superhelical Simian Virus 40 DNA to a Linear Duplex by S1 Nuclease

S(1) nuclease, the single-strand specific nuclease from Aspergillus oryzae can cleave both strands of circular covalently closed, superhelical simian virus 40 (SV40) DNA to generate unit length linear duplex molecules with intact single strands. But circular, covalently closed, nonsuperhelical DNA, as well as linear duplex molecules, are relatively resistant to attack by the enzyme. These findings indicate that unpaired or weakly hydrogen-bonded regions, sensitive to the single strand-specific nuclease, occur or can be induced in superhelical DNA. Nicked, circular SV40 DNA can be cleaved on the opposite strand at or near the nick to yield linear molecules. S(1) nuclease may be a useful reagent for cleaving DNAs at regions containing single-strand nicks. Unlike the restriction endonucleases, S(1) nuclease probably does not cleave SV40 DNA at a specific nucleotide sequence. Rather, the sites of cleavage occur within regions that are readily denaturable in a topologically constrained superhelical molecule. At moderate salt concentrations (75 mM) SV40 DNA is cleaved once, most often within either one of the two following regions: the segments defined as 0.15 to 0.25 and 0.45 to 0.55 SV40 fractional length, clockwise, from the EcoR(I) restriction endonuclease cleavage site (defined as the zero position on the SV40 DNA map). In higher salt (250 mM) cleavage occurs preferentially within the 0.45 to 0.55 segment of the map.     

Mechanism of DNA cleavage and substrate recognition by a bovine apurinic endonuclease

The location of the phosphodiester bond cleaved by homogeneous Mg2+-dependent apurinic endodeoxyribonuclease (EC 3.1.25.2; APE) of bovine calf thymus has been determined by using a 21-mer oligonucleotide containing a single central apurinic site as a substrate. A single product of cleavage consistent with cleavage of the oligonucleotide 5' to the apurinic site, and leaving a 3' hydroxyl group, was identified. This enzyme is, therefore, a class II apurinic endonuclease. The substrate specificities of this enzyme have been determined by using a variety of natural and synthetic DNAs or oligonucleotides containing base-free sites. Calf thymus APE has an absolute requirement for a double-stranded DNA and requires an abasic site as a substrate. The presence of a base fragment such as a urea residue, an alkoxyamine group attached to the C'-1 position of the abasic site, or reduction of the C'-1 aldehyde abolishes the APE activity of this enzyme. Synthetic abasic sites containing either ethylene glycol, propanediol, or tetrahydrofuran interphosphate linkages are excellent substrates for bovine APE. These results indicate that APE has no absolute requirement for either ring-opened or ring-closed deoxyribose moieties in its recognition of DNA-cleavage substrates. The enzyme may interact with the pocket in duplex DNA that results from the base loss or with the altered conformations of the phosphodiester backbone that result from the abasic site.     

Mechanism of exonuclease action of BAL 31 nuclease

Two kinetically and molecularly distinct forms ('fast' (F) and 'slow' (S] of nuclease BAL 31 from Alteromonas espejiana effect the length reduction of linear duplex DNAs through a 3'----5'-directed exonuclease activity in conjunction with an endonuclease activity against the 5'-terminated single-stranded tails generated by the exonuclease activity. No evidence for a 5'----3' mode of exonuclease action was seen. Single-stranded DNA is degraded predominantly by the 3'----5' exonuclease action. There is a pronounced decrease, to roughly constant values, of the average lengths of the tails in partially digested duplexes at a constant extent of digestion with increasing nuclease concentration. This decrease correlates with an increasing extent of ligatability, in the absence of repair, under conditions favoring the joining of fully base-paired ends. The exonuclease action, at least against duplex substrates, is quasi-processive and removes approx. 18 and 28 nucleotides per productive enzyme-substrate encounter for the S and F species, respectively. The dependence on Ca2+ and Mg2+ concentrations of the activities has been determined.     

A vaccinia virus DNase preparation which cross-links superhelical DNA.

Multiple DNA-dependent enzyme activities have been detected in highly purified preparations of a single-strand-specific nuclease from vaccinia virus. These enzyme preparations were extensively purified and characterized by using superhelical DNAs as substrates. In particular, the nuclease activity was monitored by the extent of conversion of supercoiled closed duplex DNA (DNA I) to nicked circular DNA (DNA II), which could subsequently be converted to duplex linear DNA (DNA III) by prolonged incubation with the enzyme. DNA species which were not substrates for the enzyme included relaxed closed duplex DNA, DNA II which had been prepared by nuclease S1 treatment or by photochemical nicking of DNA I, and DNA III. With plasmid pSM1 DNA as substrate, the extent of cleavage of DNA I to DNA II was found to increase with superhelix density above a threshold value of about -0.06. The linear reaction products were examined by gel electrophoresis after restriction enzyme digestion of the DNAs from plasmids pSM1 and pBR322 and of the viral DNAs from bacteriophage phi X174 (replicative form) and simian virus 40, and the map coordinate locations of the scissions were determined. These products were further examined by electron microscopy and by gel electrophoresis under denaturing conditions. Electron micrographs taken under partially denaturing conditions revealed molecules with terminal loops or hairpins such as would result from the introduction of cross-links at the cutting sites. These species exhibited snapback renaturation. The denaturing gel electrophoresis experiments revealed the appearance of new bands at locations consistent with terminal cross-linking. With pSM1 and pBR322 DNAs, this band was shown to contain DNA that was approximately twice the length of a linear single strand. The terminal regions of the cross-linked linear duplex reaction products were sensitive to nuclease S1 but insensitive to proteinase K, suggesting that the structure is a hairpin loop not maintained by a protein linker. A similar structure is found in mature vaccinia virus DNA.     

DNA abasic lesions in a different light: solution structure of an endogenous topoisomerase II poison

Topoisomerase II is the target for several anticancer drugs that "poison" the enzyme and convert it to a cellular toxin by increasing topoisomerase II-mediated DNA cleavage. In addition to these "exogenous topoisomerase II poisons," DNA lesions such as abasic sites act as "endogenous poisons" of the enzyme. Drugs and lesions are believed to stimulate DNA scission by altering the structure of the double helix within the cleavage site of the enzyme. However, the structural alterations that enhance cleavage are unknown. Since abasic sites are an intrinsic part of the genetic material, they represent an attractive model to assess DNA distortions that lead to altered topoisomerase II function. Therefore, the structure of a double-stranded dodecamer containing a tetrahydrofuran apurinic lesion at the +2 position of a topoisomerase II DNA cleavage site was determined by NMR spectroscopy. Three major features distinguished the apurinic structure ( = 0.095) from that of wild-type ( = 0.077). First, loss of base stacking at the lesion collapsed the major groove and reduced the distance between the two scissile phosphodiester bonds. Second, the apurinic lesion induced a bend that was centered about the topoisomerase II cleavage site. Third, the base immediately opposite the lesion was extrahelical and relocated to the minor groove. All of these structural alterations have the potential to influence interactions between topoisomerase II and its DNA substrate.     

Response of phage T4 polynucleotide kinase toward dinucleotides containing apurinic sites: design of a 32P-postlabeling assay for apurinic sites in DNA

We have examined the capacity of bacteriophage T4 polynucleotide kinase (EC 2.7.1.78) to phosphorylate the partially depurinated products of d-ApA, namely, d-SpA and d-ApS (where S represents an apurinic deoxyribose group). It was observed that the enzyme acted only on the latter isomer. Since molecules of this type (d-NpS) are the sole apurinic site containing products resulting from the combined digestion of lightly depurinated DNA by snake venom phosphodiesterase and calf alkaline phosphatase [Weinfeld, M., Liuzzi, M., & Paterson, M. C. (1989) Nucleic Acids Res. 17, 3735-3745], we were able to devise a postlabeling assay for these biologically important DNA lesions. The method offers several advantages, including (a) elimination of the need for prelabeled DNA, (b) high (femtomole range) sensitivity, and (c) nearest-neighbor analysis of bases 5' to apurinic/apyrimidinic sites. Using this assay, we obtained a value for the rate of depurination of form I pRSVneo plasmid DNA, incubated at pH 5.2 at 70 degrees C, of approximately 3.3 apurinic sites per plasmid molecule per hour. This value compares favorably with previously published data of others, acquired by alternative approaches. The rate of depurination of poly(dA), treated in a similar fashion, was found to be approximately 1 base per 10(3) nucleotides per hour.     

Extracellular nucleases of Pseudomonas BAL 31. I. Characterization of single strand-specific deoxyriboendonuclease and double-strand deoxyriboexonuclease activities.

The culture medium of Pseudomonas BAL 31 contains endonuclease activities which are highly specific for single-stranged DNA and for the single-stranded or weakly hydrogen-bonded regions in supercoiled closed circular DNA. Exposure of nicked DNA to the culture medium results in cleavage of the strang opposite the sites of preexisting single-strand scissions. At least some of the linear duplex molecules derived by cleavage of supercoiled closed circular molecules contain short single-stranded ends. Single-strand scissions are not introduced into intact, linear duplex DNA or unsupercoiled covalently closed circular DNA. Under these same reaction conditions, 0X174 phage DNA is extensively degraded and PM2 form I DNA is quantitatively converted to PM2 form III linear duplexes. Prolonged exposure of this linear duplex DNA to the concentrated culture medium reveals the presence of a double-strand exonuclease activity that progressively reduces the average length of the linear duplex. These nuclease activities persist at ionic strengths up to 4 M and are not eliminated in the presence of 5% sodium dodecyl sulfate. Calcium and magnesium ion are both required for optimal activity. Although the absence of magnesium ion reduces the activities, the absence of calcium ion irreversibly eliminates all the activities.     

S1 nuclease does not cleave DNA at single-base mis-matches

Three assays have been designed to detect the cleavage of duplex phi X174 DNA at single-base mis-matches. Studies with S1 nuclease failed to detect cleavage at mis-matches. S1 nuclease digestion at 37 and 55 degrees C failed to produce a preferential degradation of a multiply mis-matched heteroduplex when compared to a mis-match-free homo-duplex as analyzed by sedimentation on sucrose gradients. Other heteroduplex templates were not cleaved by S1 nuclease at a defined single-base mis-match when assayed by gel electrophoresis or by marker rescue. In all cases, the amount of S1 nuclease employed was at least 10-times more than that required to render a single-stranded phi X174 DNA molecule completely acid soluble. The rate of hydrolysis of single-base mis-matches by S1 nuclease was estimated to be less than 0.016% of the rate at a base in single-strand phi X174 DNA. In no instance did we detect activity by S1 nuclease directed at mis-matched sites in our template molecules. Similarly, the single-strand specific endonuclease from Neurospora crassa does not cleave heteroduplex templates at a defined single-base mis-match when assayed by marker rescue.     

Specific cleavage of DNA molecules at RecA-mediated triple-strand structure

A novel procedure to cleave DNA molecules at any desired base sequence is presented. This procedure is based upon our finding that double-stranded DNA molecules at a site where RecA-mediated triple-stranded DNA structure with a complimentary deoxyoligonucleotide is located can be cleaved by a single-strand specific nuclease, such as nuclease S1 or BAL31, between the first base at the 5′ termini of the deoxyoligonucleotides and the nearest base proximal to the 5′ termini. Accordingly, the sequence as well as the number of the cleavage sites to be cleaved can be custom designed by selecting deoxyoligonucleotides with specific base sequences for triple-stranded DNA formation. The basic characteristics of the cleavage reaction and typical applications of the procedure are presented with actual results, including those which involve cleavage of complex genomic DNA at the very sites one desires.     

UvrABC nuclease complex repairs thymine glycol, an oxidative DNA base damage

The UvrABC nuclease complex recognizes a wide spectrum of DNA lesions including pyrimidine dimers, bulky chemical adducts and O6-methylguanine. In this study we have demonstrated that the UvrABC complex is also able to incise PM2 DNA containing the oxidative DNA lesion, thymine glycol. However, DNA containing dihydrothymine, a lesion with a similar structure to thymine glycol, was not incised. The UvrABC complex was also able to incise DNA containing reduced apurinic sites or apurinic sites modified with O-alkyl hydroxylamines, but not DNA containing apurinic sites or urea residues. In vivo, in the absence of base-excision repair, nucleotide excision repair was operable on phi X-174 RF transfecting DNA containing thymine glycols. The level of the repair was found to be directly related to the level of the UvrABC complex. Thus, UvrABC-mediated nucleotide excision repair appears to play a role in the repair of thymine glycol, an oxidative DNA-base lesion that is produced by ionizing radiation or formed during oxidative respiration.     

S1-sensitive sites in DNA after gamma-irradiation

DNA from gamma-irradiated T1 bacteriophages was analyzed for "single-stranded" sites by cleavage with S1 nuclease from Aspergillus oryzae as lesion probe. The ratio of "S1-sensitive sites" to the amount of radiation-induced single-strand breaks was about one. Presumably these "denatured" sites were associated with single-strand breaks. The subsequent check for the persistence of "single-stranded" sites within the DNA molecule by thermokinetics demonstrated a strong affinity of the nuclease to its substrate, the single-stranded lesion, and a perfect excision. It is assumed that the direct absorption of radiation energy in the DNA gives rise to the formation of such bulky lesions.     

Activation of restriction endonuclease EcoRII does not depend on the cleavage of stimulator DNA.

The restriction endonuclease EcoRII is unable to cleave DNA molecules when recognition sites are very far apart. The enzyme, however can be activated in the presence of DNA molecules with a high frequency of EcoRII sites or by oligonucleotides containing recognition sites: Addition of the activator molecules stimulates cleavage of the refractory substrate. We now show that endonucleolysis of the stimulator molecules is not a necessary prerequisite of enzyme activation. A total EcoRII digest of pBR322 DNA or oligonucleotide duplexes with simulated EcoRII ends (containing the 5' phosphate group), as well as oligonucleotide duplexes containing modified bases within the EcoRII site, making them resistant to cleavage, are all capable of enzyme activation. For activation EcoRII requires the interaction with at least two recognition sites. The two sites may be on the same DNA molecule, on different oligonucleotide duplexes, or on one DNA molecule and one oligonucleotide duplex. The efficiency of functional intramolecular cooperation decreases with increasing distance between the sites. Intermolecular site interaction is inversely related to the size of the stimulator oligonucleotide duplex. The data are in agreement with a model whereby EcoRII simultaneously interacts with two recognition sites in the active complex, but cleavage of the site serving as an allosteric activator is not necessary.